In this thesis, advanced high-κ materials were employed to fabricate high-performance low-temperature polycrystalline silicon thin film transistors (TFTs). Most of the efforts were focused on exploring the deposition of high-κ films by the new atomic-vapor deposition (AVD) system, improving the performance of the poly-Si TFTs with newly-developed high-κ films, and studying the reliability of these high-κ TFTs. First of all, a new AVD system was employed for the deposition of the advanced high-κ materials. The impacts of deposition parameters, including the deposition temperature, chamber pressure, oxygen gas flow, injection frequency, and composition adjustment, were investigated systematically. The thermal stability of high-κ films was also tested by high temperature post-deposition annealing (PDA). It was found that higher deposition temperature and sufficient oxygen gas flow are essential to obtain the good quality and stoichiometric high-κ films by the AVD system. However, the large leakage current would be caused by the polycrystalline structure of HfO2 films. In contrast, HfSiOx films exhibit better thermal stability and retain the amorphous structure even after high temperature annealing. Certainly, the lower κ compared with HfO2 film is the disadvantage of the HfSiOx films. Besides, the native interfacial layer with lower κ value always exists between the thin high-κ gate dielectric and Si substrate, which defeats the purpose of EOT lowering. Next, we also tried to apply the newly-developed high-κ films to the low-temperature polycrystalline silicon (LTPS) TFTs. In this part, the structural and electrical properties of the thicker high-κ films were characterized first. Then, we performed a systematic study on the electrical properties of low-temperature-compatible p-channel poly-Si thin-film transistors (TFTs) using HfO2 or HfSiOx high-? gate dielectric. Because of their higher gate capacitance density, TFTs containing the high-? gate dielectric exhibit superior device performance in terms of higher Ion/Ioff current ratio, lower subthreshold swing (S.S.), and lower threshold voltage (Vth), relative to the conventional deposited-SiO2 counterparts, albeit with slightly higher OFF-state current. TFTs incorporating HfSiOx as the gate dielectric has 1.76 times the field-effect mobility (?FE) relative to that of the deposited-SiO2 TFTs. In contrast, the HfO2-TFTs exhibit inferior mobility. The device performance dependence on the channel length and width of poly-Si TFTs was also discussed. Furthermore, we also carefully investigated the mobility degradation mechanisms in these HfO2-TFTs. We discussed possible origins of the additional scatterings, which might be attributed to the trapped charges, fixed charges, soft phonons, and crystallization in the HfO2 films and HfO2/poly-Si channel interface. Moreover, the higher leakage current of poly-Si TFTs using high-κ gate dielectrics was also studied. Aggravated gate-induced drain leakage (GIDL) current was thought to arise from the higher induced electric field by the introduction of high-κ films, and field-emission current would be the dominant leakage mechanism. In addition, the reliabilities of these TFTs with different gate dielectrics were tested by the varying-temperature measurements and negative bias temperature instability (NBTI) stress. Obviously, the high-κ TFTs exhibit better temperature immunity over the conventional TFTs containing the deposited-SiO2 film. In comparison with the devices using different high-κ gate dielectrics, the immunity of HfSiOx-TFTs was better than that of HfO2-TFTs—in terms of Vth shift, SS degradation, ?FE degradation, and drive current deterioration—against NBTI stressing. Thus, we believe that HfSiOx, rather than HfO2, is a better candidate as the gate dielectric material for the future high-performance poly-Si TFTs.